Numerical prediction of combustion instability limit cycle oscillations for a combustor with a long flame

Li, Jingxuan; Xia, Yu; Morgans, Aimee S.; Han, Xingsi

doi:10.1016/j.combustflame.2017.06.018

Cited by 71 publications

(19 citation statements)

References 76 publications

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“…Governing equations. The flame−acoustics−flow−heater interaction problem 38,39 is modelled by solving certain equations governing fluid dynamics and the chemical combustion reaction. All these equations need to be solved simultaneously and some of them are coupled, e.g.…”

Section: Discussionmentioning

confidence: 99%

Characterizing hydrogen-fuelled pulsating combustion on thermodynamic properties of a combustor

2019

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Unlike hydrocarbon fuel, hydrogen is 'green' and attracting more and more attentions in energy and propulsion sectors due to the zero emission of CO and CO 2 . By applying numerical simulations, we explore the physics of how a hydrogen-burnt flame can sustain pulsating combustion and its impact on the thermodynamic properties of a standing-wave combustor. We also explain how implementing a heat exchanger can mitigate such pulsating combustion. The dynamic interactions of the unsteady flow-flame-acoustics-heater are examined by varying the mass flow rate ṁ H2 and the heating bands' surface temperature T H . The frequency and amplitude of the pulsating combustion are shown to depend strongly on ṁ H2 . In addition, varying T H is shown to lead to not only the molar fraction of the combustion species being changed but also the flame-sustained pulsating oscillations being mitigated somehow. Finally, nonlinearity is observed and identified in the unsteady flow velocity and the two heat sources.

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Section: Discussionmentioning

confidence: 99%

Characterizing hydrogen-fuelled pulsating combustion on thermodynamic properties of a combustor

2019

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“…Due to their versatility, accuracy, and speed, low-order network models are widely used both in industry and academia. Examples include LOTAN [21], OSCILOS [22] and TA3 [23]. See Lieuwen [24] for a detailed introduction to the methods and Bothien [25,Chapter 4] for a review of network models currently in use.…”

Section: Governing Equations Of the Network Modelmentioning

confidence: 99%

Thermoacoustic stabilization of a longitudinal combustor using adjoint methods

Aguilar

Juniper

2020

Phys. Rev. Fluids

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We construct a low order thermoacoustic network model that contains the most influential physical mechanisms of a thermoacoustic system. We apply it to a laboratory-scale longitudinal combustor that has been found to be thermoacoustically unstable in experiments. We model the flame, which is behind a bluff body, by a geometric level set method. We obtain the thermoacoustic eigenvalues of this configuration and examine a configuration in which six eigenmodes are unstable. We then derive the adjoint equations of this model and use the corresponding adjoint eigenmodes to obtain the sensitivities of the unstable eigenvalues to modifications of the model geometry. These sensitivities contain contributions from changes to the steady base flow and changes to the fluctuating flow. We find that these two contributions have similar magnitudes, showing that both contributions need to be considered. We then wrap these sensitivities within a gradient-based optimization algorithm and stabilize all six eigenvalues by changing the geometry. The required geometry changes are well approximated by the first step in the optimization process, showing that this sensitivity information is useful even before it is embedded within an optimization algorithm. We examine the acoustic energy balance during the optimization process and identify the physical mechanisms through which the algorithm is stabilizing the combustor. The algorithm works by, for each mode, reducing the work done by the flame, while simultaneously increasing the work done by the system on the outlet boundary. We find that only small geometry changes are required in order to stabilize every mode. The network model used in this study deliberately has the same structure as one used in the gas turbine industry in order to ease its implementation in practice. * Now at Norges teknisk-naturvitenskapelige universitet (NTNU);

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“…They also expressed the propagation characteristics in the long flame region and validated their analysis with experimental data which measured limit cycle characteristics. That study, however, did not analyze heat-acoustic propagation in the entire combustor and was unable to show the change in operating conditions over time [22].…”

Section: Literature Survey Of the Combustion Instabilitymentioning

confidence: 99%

“…The previous model by Li et al [22] is a useful concept but it is not adequate to assess a segmented instability because it only considers one combustor volume and long flames. To develop a segmented combustor and combustion instability model, a node analysis was used, with further experimental data on the heat release, the frequency spectra of velocity, and pressure perturbations.…”

Section: Objective and Outline Of This Papermentioning

confidence: 99%

A Real-Time Combustion Instability Simulation with Comprehensive Thermo-Acoustic Dynamic Model

et al. 2018

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The thermo-acoustic instability in the combustion process of a gas turbine is caused by the interaction of the heat release mechanism and the pressure perturbation. These acoustic vibrations cause fatigue failure of the combustor and decrease the combustion efficiency. This study aims to develop a segmented dynamic thermo-acoustic model to understand combustion instability of a gas turbine. Then, the combustion instability was designed using the acoustic heat release model, and the designed instability model was segmented using the finite difference method, to evaluate the characteristics of flame propagation at each node. The combustion instability model was validated using experimental data to verify the instability amplitude. Also, the optimal node number was determined using the adiabatic flame temperature response. 10 nodes were selected in this study. A sensitivity analysis showed the predicted instability amplitude decreased when the nodes increased until node 4, due to heat generation. However, above 4 nodes the amplitude decreased, since the combustion outlet was directly connected to the ambient. As a result, the segmented combustion instability model was able to evaluate the flame propagation characteristics more accurately and found the largest area of instability was near the flame area.

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Numerical prediction of combustion instability limit cycle oscillations for a combustor with a long flame

Cited by 71 publications

References 76 publications

Characterizing hydrogen-fuelled pulsating combustion on thermodynamic properties of a combustor

Characterizing hydrogen-fuelled pulsating combustion on thermodynamic properties of a combustor

Thermoacoustic stabilization of a longitudinal combustor using adjoint methods

A Real-Time Combustion Instability Simulation with Comprehensive Thermo-Acoustic Dynamic Model

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